Multi-view signal codec

ABSTRACT

Embodiments are described which exploit a finding, according to which a higher compression rate or better rate/distortion ratio may be achieved by adopting or predicting second coding parameters used for encoding a second view of the multi-view signal from first coding parameters used in encoding a first view of the multi-view signal. In other words, the inventors found out that the redundancies between views of a multi-view signal are not restricted to the views themselves, such as the video information thereof, but that the coding parameters in parallely encoding these views show similarities which may be exploited in order to further improve the coding rate.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a Continuation of U.S. patent application Ser. No. 15/386,634, filed Dec. 21, 2016, which is a Continuation of U.S. patent application Ser. No. 13/762,608, filed Feb. 8, 2013, now U.S. Pat. No. 9,648,298, which is a Continuation of International Application No. PCT/EP2011/063852, filed Aug. 11, 2011, and additionally claims priority from U.S. Application No. 61/372,785, filed Aug. 11, 2010. The subject matter of each of the foregoing applications and patent is incorporated herein by reference in entirety.

BACKGROUND OF THE INVENTION

The present invention relates to coding of multi-view signals.

Multi-view signals are involved in many applications, such as 3D video applications including, for example, stereo and multi-view displays, free viewpoint video applications, etc. For stereo and multi-view video content, the MVC standard has been specified [1, 2]. This standard compresses video sequences from a number of adjacent cameras. The MVC decoding process only reproduces these camera views at their original camera positions. For different multi-view displays however, a different number of views with different spatial positions are necessitated such that additional views, e.g. between the original camera positions, are necessitated.

The difficulty in handling multi-view signals is the huge amount of data necessary to convey information on the multiple views included in the multi-view signal. In case of the just mentioned requirement to enable intermediate view extraction/synthesis, the situation gets even worse, since in this case the videos associated with the individual views may be accompanied by supplementary data such as depth/disparity map data enabling re-projecting the respective view into another view, such as an intermediate view. Owing to the huge amount of data, it is very important to maximize the compression rate of the multi-view signal codec as far as possible.

SUMMARY

According to an embodiment, a decoder may be configured to: reconstruct a first view of a multi-view signal from a data stream by, according to first coding parameters obtained from the data stream, predicting a current portion of the first view from a first previously reconstructed portion of the multi-view signal, reconstructed from the data stream by the decoder prior to the reconstruction of the current portion of the first view and correcting a prediction error of the prediction of the current portion of the first view using first correction data contained in the data stream; at least partially adopt or predict second coding parameters from the first coding parameters; and reconstruct a second view of the multi-view signal from the data stream by, according to the second coding parameters, predicting a current portion of the second view from a second previously reconstructed portion of the multi-view signal, reconstructed from the data stream by the decoder prior to the reconstruction of the current portion of the second view and correcting a prediction error of the prediction of the current portion of the second view using second correction data contained in the data stream.

According to another embodiment, an encoder may be configured to: encode a first view of a multi-view signal into a data stream by determining first coding parameters, according to the first coding parameters, predicting a current portion of the first view from a first previously encoded portion of the multi-view signal, encoded into the data stream by the encoder prior to the encoding of the current portion of the first view, and determining a prediction error of the prediction of the current portion of the first view in order to obtain first correction data, and inserting the first coding parameters and the first correction data into the data stream; encode a second view of the multi-view signal into the data stream by, determining second coding parameters by adopting or predicting the second coding parameters from the first coding parameters; according to the second coding parameters, predicting a current portion of the second view from a second previously encoded portion of the multi-view signal, encoded into the data stream by the encoder prior to the encoding of the current portion of the second view and determining a prediction error of the prediction of the current portion of the second view in order to obtain second correction data contained in the data stream, inserting the second correction data into the data stream.

According to another embodiment, a data stream may have: a first part into which a first view of a multi-view signal is encoded, the first part having first correction parameters and first coding parameters such that, according to the first coding parameters, a current portion of the first view is predictable from a first previously encoded portion of the multi-view signal, encoded into the data stream prior to the current portion of the first view, and a prediction error of the prediction of the current portion of the first view is correctable using the first correction data, and a second part into which a second view of the multi-view signal is encoded, the second part having second correction parameters such that according to second coding parameters predictable from, or adopted from the first coding parameters, a current portion of the second view is predictable from a second previously encoded portion of the multi-view signal, encoded into the data stream prior to the encoding of the current portion of the second view and a prediction error of the prediction of the current portion of the second view is correctable using the second correction data.

According to another embodiment, a decoding method may have the steps of: reconstructing a first view of a multi-view signal from a data stream by, according to first coding parameters obtained from the data stream, predicting a current portion of the first view from a first previously reconstructed portion of the multi-view signal, reconstructed from the data stream by the decoder prior to the reconstruction of the current portion of the first view and correcting a prediction error of the prediction of the current portion of the first view using first correction data contained in the data stream; at least partially adopting or predicting second coding parameters from the first coding parameters; and reconstructing a second view of the multi-view signal from the data stream by, according to the second coding parameters, predicting a current portion of the second view from a second previously reconstructed portion of the multi-view signal, reconstructed from the data stream by the decoder prior to the reconstruction of the current portion of the second view and correcting a prediction error of the prediction of the current portion of the second view using second correction data contained in the data stream.

According to another embodiment, an encoding method may have the steps of: encoding a first view of a multi-view signal into a data stream by determining first coding parameters, according to the first coding parameters, predicting a current portion of the first view from a first previously encoded portion of the multi-view signal, encoded into the data stream by the encoder prior to the encoding of the current portion of the first view, and determining a prediction error of the prediction of the current portion of the first view in order to obtain first correction data, and inserting the first coding parameters and the first correction data into the data stream; and encoding a second view of the multi-view signal into the data stream by, determining second coding parameters by adopting or predicting the second coding parameters from the first coding parameters; according to the second coding parameters, predicting a current portion of the second view from a second previously encoded portion of the multi-view signal, encoded into the data stream by the encoder prior to the encoding of the current portion of the second view and determining a prediction error of the prediction of the current portion of the second view in order to obtain second correction data contained in the data stream, inserting the second correction data into the data stream.

Another embodiment may have a computer program having a program code for performing, when running on a computer, the above methods.

The present application provides embodiments exploiting a finding, according to which a higher compression rate or better rate/distortion ratio may be achieved by adopting or predicting second coding parameters used for encoding a second view of the multi-view signal from first coding parameters used in encoding a first view of the multi-view signal. In other words, the inventors found out that the redundancies between views of a multi-view signal are not restricted to the views themselves, such as the video information thereof, but that the coding parameters in parallely encoding these views show similarities which may be exploited in order to further improve the coding rate.

Some embodiments of the present application additionally exploit a finding according to which the segmentation of a depth/disparity map associated with a certain frame of a video of a certain view, used in coding the depth/disparity map, may be determined or predicted using an edge detected in the video frame as a hint, namely by determining a wedgelet separation line so as to extend along the edge in the video frame. Although the edge detection increases the complexity at the decoder side, the deficiency may be acceptable in application scenarios where low transmission rates at acceptable quality is more important than complexity issues. Such scenarios may involve broadcast applications where the decoders are implemented as stationary devices.

Further, some embodiments of the present application additionally exploit a finding according to which the view the coding parameters of which are adopted/predicted from coding information of another view, may be coded, i.e. predicted and residual-corrected, in at a lower spatial resolution, with thereby saving coded bits, if the adoption/prediction of the coding parameters includes scaling of these coding parameters in accordance with a ratio between the spatial resolutions.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the present application are described below with respect to the figures among which:

FIG. 1 shows a block diagram of an encoder according to an embodiment;

FIG. 2 shows a schematic diagram of a portion of a multi-view signal for illustration of information reuse across views and video depth/disparity boundaries;

FIG. 3 shows a block diagram of a decoder according to an embodiment;

FIG. 4 Prediction structure and motion/disparity vectors in multi-view coding on the example of two views and two time instances;

FIG. 5 Point correspondences by disparity vector between adjacent views;

FIG. 6 Intermediate view synthesis by scene content projection from views 1 and 2, using scaled disparity vectors;

FIG. 7 N-view extraction from separately decoded color and supplementary data for generating intermediate views at arbitrary viewing positions; and

FIG. 8 N-view extraction example of a two-view bitstream for a 9 view display.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 shows an encoder for encoding a multi-view signal in accordance with an embodiment. The multi-view signal of FIG. 1 is illustratively indicated at 10 as comprising two views 12 ₁ and 12 ₂, although the embodiment of FIG. 1 would also be feasible with a higher number of views. Further, in accordance with the embodiment of FIG. 1, each view 12 ₁ and 12 ₂ comprises a video 14 and depth/disparity map data 16, although many of the advantageous principles of the embodiment described with respect to FIG. 1 could also be advantageous if used in connection with multi-view signals with views not comprising any depth/disparity map data. Such generalization of the present embodiment is described further below subsequent to the description of FIGS. 1 to 3.

The video 14 of the respective views 12 ₂ and 12 ₂ represent a spatio-temporal sampling of a projection of a common scene along different projection/viewing directions. Advantageously, the temporal sampling rate of the videos 14 of the views 12 ₁ and 12 ₂ are equal to each other although this constraint does not have to be necessarily fulfilled. As shown in FIG. 1, advantageously each video 14 comprises a sequence of frames with each frame being associated with a respective time stamp t, t−1, t−2, . . . . In FIG. 1 the video frames are indicated by v_(view number, time stamp number). Each frame v_(i,t) represents a spatial sampling of the scene i along the respective view direction at the respective time stamp t, and thus comprises one or more sample arrays such as, for example, one sample array for luma samples and two sample arrays with chroma samples, or merely luminance samples or sample arrays for other color components, such as color components of an RGB color space or the like. The spatial resolution of the one or more sample arrays may differ both within one video 14 and within videos 14 of different views 12 i and 122.

Similarly, the depth/disparity map data 16 represents a spatio-temporal sampling of the depth of the scene objects of the common scene, measured along the respective viewing direction of views 12 ₁ and 12 ₂. The temporal sampling rate of the depth/disparity map data 16 may be equal to the temporal sampling rate of the associated video of the same view as depicted in FIG. 1, or may be different therefrom. In the case of FIG. 1, each video frame v has associated therewith a respective depth/disparity map d of the depth/disparity map data 16 of the respective view 12 i and 12 ₂. In other words, in the example of FIG. 1, each video frame v_(i,t) of view i and time stamp t has a depth/disparity map d_(i,t) associated therewith. With regard to the spatial resolution of the depth/disparity maps d, the same applies as denoted above with respect to the video frames. That is, the spatial resolution may be different between the depth/disparity maps of different views.

In order to compress the multi-view signal 10 effectively, the encoder of FIG. 1 parallely encodes the views 12 ₁ and 12 ₂ into a data stream 18, However, coding parameters used for encoding the first view 12 ₁ are re-used in order to adopt same as, or predict, second coding parameters to be used in encoding the second view 12 ₂. By this measure, the encoder of FIG. 1 exploits the fact discovered by the inventors, according to which parallel encoding of views 12 ₁ and 12 results in the encoder determining the coding parameters for these views similarly, so that redundancies between these coding parameters may be exploited effectively in order to increase the compression rate or rate/distortion ratio (with distortion measured, for example, as a mean distortion of both views and the rate measured as a coding rate of the whole data stream 18).

In particular, the encoder of FIG. 1 is generally indicated by reference sign 20 and comprises an input for receiving the multi-view signal 10 and an output for outputting the data stream 18. As can be seen in FIG. 2, the encoder 20 of FIG. 1 comprises two coding branches per view 12 ₁ and 12 ₂, namely one for the video data and the other for the depth/disparity map data. Accordingly, the encoder 20 comprises a coding branch 22 _(v,1) for the video data of view 1, a coding branch 22 _(d,1) for the depth disparity map data of view 1, a coding branch 22 _(v,2) for the video data of the second view and a coding branch 22 _(d,2) for the depth/disparity map data of the second view. Each of these coding branches 22 is constructed similarly. In order to describe the construction and functionality of encoder 20, the following description starts with the construction and functionality of coding branch 22 _(v,1). This functionality is common to all branches 22. Afterwards, the individual characteristics of the branches 22 are discussed.

The coding branch 22 _(v,1) is for encoding the video 14 ₁ of the first view 12 ₁ of the multi-view signal 12, and accordingly branch 22 _(v,1) has an input for receiving the video 14 ₁. Beyond this, branch 22 _(v,1) comprises, connected in series to each other in the order mentioned, a subtracter 24, a quantization/transform module 26, a requantization/inverse-transform module 28, an adder 30, a further processing module 32, a decoded picture buffer 34, two prediction modules 36 and 38 which, in turn, are connected in parallel to each other, and a combiner or selector 40 which is connected between the outputs of the prediction modules 36 and 38 on the one hand the inverting input of subtracter 24 on the other hand. The output of combiner 40 is also connected to a further input of adder 30. The non-inverting input of subtracter 24 receives the video 14 i.

The elements 24 to 40 of coding branch 22 _(v,1) cooperate in order to encode video 14 ₁. The encoding encodes the video 14 ₁ in units of certain portions. For example, in encoding the video 14 ₁, the frames v_(1,k) are segmented into segments such as blocks or other sample groups. The segmentation may be constant over time or may vary in time. Further, the segmentation may be known to encoder and decoder by default or may be signaled within the data stream 18. The segmentation may be a regular segmentation of the frames into blocks such as a non-overlapping arrangement of blocks in rows and columns, or may be a quad-tree based segmentation into blocks of varying size. A currently encoded segment of video 14 ₁ entering at the non-inverting input of subtracter 24 is called a current portion of video 14 ₁ in the following description.

Prediction modules 36 and 38 are for predicting the current portion and to this end, prediction modules 36 and 38 have their inputs connected to the decoded picture buffer 34. In effect, both prediction modules 36 and 38 use previously reconstructed portions of video 14 ₁ residing in the decoded picture buffer 34 in order to predict the current portion/segment entering the non-inverting input of subtracter 24. In this regard, prediction module 36 acts as an intra predictor spatially predicting the current portion of video 14 i from spatially neighboring, already reconstructed portions of the same frame of the video 14 i, whereas the prediction module 38 acts as an inter predictor temporally predicting the current portion from previously reconstructed frames of the video 14 ₁. Both modules 36 and 38 perform their predictions in accordance with, or described by, certain prediction parameters. To be more precise, the latter parameters are determined be the encoder 20 in some optimization framework for optimizing some optimization aim such as optimizing a rate/distortion ratio under some, or without any, constraints such as maximum bitrate.

For example, the intra prediction module 36 may determine spatial prediction parameters for the current portion such as a prediction direction along which content of neighboring, already reconstructed portions of the same frame of video 14 ₁ is expanded/copied into the current portion to predict the latter. The inter prediction module 38 may use motion compensation so as to predict the current portion from previously reconstructed frames and the inter prediction parameters involved therewith may comprise a motion vector, a reference frame index, a motion prediction subdivision information regarding the current portion, a hypothesis number or any combination thereof. The combiner 40 may combine one or more of predictions provided by modules 36 and 38 or select merely one thereof. The combiner or selector 40 forwards the resulting prediction of the current portion to the inserting input of subtractor 24 and the further input of adder 30, respectively.

At the output of subtractor 24, the residual of the prediction of the current portion is output and quantization/transform module 36 is configured to transform this residual signal with quantizing the transform coefficients. The transform may be any spectrally decomposing transform such as a DCT. Due to the quantization, the processing result of the quantization/transform module 26 is irreversible. That is, coding loss results. The output of module 26 is the residual signal 42 ₁ to be transmitted within the data stream. The residual signal 42 ₁ is dequantized and inverse transformed in module 28 so as to reconstruct the residual signal as far as possible, i.e. so as to correspond to the residual signal as output by subtracter 24 despite the quantization noise. Adder 30 combines this reconstructed residual signal with the prediction of the current portion by summation. Other combinations would also be feasible. For example, the subtractor 24 could operate as a divider for measuring the residuum in ratios, and the adder could be implemented as a multiplier to reconstruct the current portion, in accordance with an alternative. The output of adder 30, thus, represents a preliminary reconstruction of the current portion. Further processing, however, in module 32 may optionally be used to enhance the reconstruction. Such further processing may, for example, involve deblocking, adaptive filtering and the like. All reconstructions available so far are buffered in the decoded picture buffer 34. Thus, the decoded picture buffer 34 buffers previously reconstructed frames of video 14 ₁ and previously reconstructed portions of the current frame which the current portion belongs to.

In order to enable the decoder to reconstruct the multi-view signal from data stream 18, quantization/transform module 26 forwards the residual signal 42 ₁ to a multiplexer 44 of encoder 20. Concurrently, prediction module 36 forwards intra prediction parameters 46 ₁ to multiplexer 44, inter prediction module 38 forwards inter prediction parameters 48 ₁ to multiplexer 44 and further processing module 32 forwards further-processing parameters 50 ₁ to multiplexer 44 which, in turn, multiplexes or inserts all this information into data stream 18.

As became clear from the above discussion in accordance with the embodiment of FIG. 1, the encoding of video 14 ₁ by coding branch 22 _(v,1) is self-contained in that the encoding is independent from the depth/disparity map data 16 ₁ and the data of any of the other views 12 ₂. From a more general point of view, coding branch 22 _(v,1) may be regarded as encoding video 14 ₁ into the data stream 18 by determining coding parameters and, according to the first coding parameters, predicting a current portion of the video 14 ₁ from a previously encoded portion of the video 14 ₁, encoded into the data stream 18 by the encoder 20 prior to the encoding of the current portion, and determining a prediction error of the prediction of the current portion in order to obtain correction data, namely the above-mentioned residual signal 42 ₁. The coding parameters and the correction data are inserted into the data stream 18.

The just-mentioned coding parameters inserted into the data stream 18 by coding branch 22 _(v,1) may involve one, a combination or, or all of the following:

-   -   First, the coding parameters for video 14 ₁ may define/signal         the segmentation of the frames of video 14 ₁ as briefly         discussed before.     -   Further, the coding parameters may comprise coding mode         information indicating for each segment or current portion,         which coding mode is to be used to predict the respective         segment such as intra prediction, inter prediction, or a         combination thereof.     -   The coding parameters may also comprise the just-mentioned         prediction parameters such as intra prediction parameters for         portions/segments predicted by intra prediction, and inter         prediction parameters for inter predicted portions/segments.     -   The coding parameters may, however, additionally comprise         further-processing parameters 50 ₁ signalling to the decoding         side how to further process the already reconstructed portions         of video 14 ₁ before using same for predicting the current or         following portions of video 14 ₁. These further processing         parameters 50 i may comprise indices indexing respective         filters, filter coefficients or the like.     -   The prediction parameters 46 ₁, 48 ₁ and the further processing         parameters 50 ₁ may even additionally comprise sub-segmentation         data in order to define a further sub-segmentation relative to         the afore-mentioned segmentation defining the granularity of the         mode selection, or defining a completely independent         segmentation such as for the appliance of different adaptive         filters for different portions of the frames within the         further-processing.     -   Coding parameters may also influence the determination of the         residual signal and thus, be part of the residual signal 42 ₁.         For example, spectral transform coefficient levels output by         quantization/transform module 26 may be regarded as correction         data, whereas the quantization step size may be signalled within         the data stream 18 as well, and the quantization step size         parameter may be regarded as a coding parameter in the sense of         the description brought forward below.     -   The coding parameters may further define prediction parameters         defining a second-stage prediction of the prediction residual of         the first prediction stage discussed above. Intra/inter         prediction may be used in this regard.

In order to increase the coding efficiency, encoder 20 comprises a coding information exchange module 52 which receives all coding parameters and further information influencing, or being influenced by, the processing within modules 36, 38 and 32, for example, as illustratively indicated by vertically extending arrows pointing from the respective modules down to coding information exchange module 52. The coding information exchange module 52 is responsible for sharing the coding parameters and optionally further coding information among the coding branches 22 so that the branches may predict or adopt coding parameters from each other. In the embodiment of FIG. 1, an order is defined among the data entities, namely video and depth/disparity map data, of the views 12 ₁ and 12 ₂ of multi-view signal 10 to this end. In particular, the video 14 ₁ of the first view 12 ₁ precedes the depth/disparity map data 16 ₁ of the first view followed by the video 14 ₂ and then the depth/disparity map data 16 ₂ of the second view 12 ₂ and so forth. It should be noted here that this strict order among the data entities of multi-view signal 10 does not need to be strictly applied for the encoding of the entire multi-view signal 10, but for the sake of an easier discussion, it is assumed in the following that this order is constant. The order among the data entities, naturally, also defines an order among the branches 22 which are associated therewith.

As already denoted above, the further coding branches 22 such as coding branch 22 _(d,1), 22 _(v,2) and 22 _(d,2) act similar to coding branch 22 _(v,1) in order to encode the respective input 16 ₁, 14 ₂ and 16 ₂, respectively. However, due to the just-mentioned order among the videos and depth/disparity map data of views 12 ₁ and 12 ₂, respectively, and the corresponding order defined among the coding branches 22, coding branch 22 _(d,1) has, for example, additional freedom in predicting coding parameters to be used for encoding current portions of the depth/disparity map data 16 ₁ of the first view 12 ₁. This is because of the afore-mentioned order among video and depth/disparity map data of the different views: For example, each of these entities is allowed to be encoded using reconstructed portions of itself as well as entities thereof preceding in the afore-mentioned order among these data entities. Accordingly, in encoding the depth/disparity map data 16 ₁, the coding branch 22 _(d,1) is allowed to use information known from previously reconstructed portions of the corresponding video 14 ₁. How branch 22 _(d,1) exploits the reconstructed portions of the video in order to predict some property of the depth/disparity map data 16 ₁, which enables a better compression rate of the compression of the depth/disparity map data 16 ₁, is described in more detail below. Beyond this, however, coding branch 22 _(d,1) is able to predict/adopt coding parameters involved in encoding video 14 ₁ as mentioned above, in order to obtain coding parameters for encoding the depth/disparity map data 16 ₁. In case of adoption, the signaling of any coding parameters regarding the depth/disparity map data 16 ₁ within the data stream 18 may be suppressed. In case of prediction, merely the prediction residual/correction data regarding these coding parameters may have to be signaled within the data stream 18. Examples for such prediction/adoption of coding parameters is described further below, too.

Additional prediction capabilities are present for the subsequent data entities, namely video and the depth/disparity map data 16 ₂ of the second view 12 ₂. Regarding these coding branches, the inter prediction module thereof is able to not only perform temporal prediction, but also inter-view prediction. The corresponding inter prediction parameters comprise similar information as compared to temporal prediction, namely per interview predicted segment, a disparity vector, a view index, a reference frame index and/or an indication of a number of hypotheses, i.e. the indication of a number of inter predictions participating in forming the inter-view inter prediction by way of summation, for example. Such inter-view prediction is available not only for branch 22 _(v,2) regarding the video 14 ₂, but also for the inter prediction module 38 of branch 22 _(d,2) regarding the depth/disparity map data 16 ₂. Naturally, these inter-view prediction parameters also represent coding parameters which may serve as a basis for adoption/prediction for subsequent view data of a possible third view which is, however, not shown in FIG. 1.

Due to the above measures, the amount of data to be inserted into the data stream 18 by multiplexer 44 is further lowered. In particular, the amount of coding parameters of coding branches 22 _(d,1), 22 _(v,2) and 22 _(d,2) may be greatly reduced by adopting coding parameters of preceding coding branches or merely inserting prediction residuals relative thereto into the data stream 28 via multiplexer 44. Due to the ability to choose between temporal and interview prediction, the amount of residual data 42 ₃ and 42 ₄ of coding branches 22 _(v,2) and 22 _(d,2) may be lowered, too. The reduction in the amount of residual data over-compensates the additional coding effort in differentiating temporal and inter-view prediction modes.

In order to explain the principles of coding parameter adoption/prediction in more detail, reference is made to FIG. 2. FIG. 2 shows an exemplary portion of the multi-view signal 10. FIG. 2 illustrates video frame v_(1,t) as being segmented into segments or portions 60 a, 60 b and 60 c. For simplification reasons, only three portions of frame v_(1,t) are shown, although the segmentation may seamlessly and gaplessly divide the frame into segments/portions. As mentioned before, the segmentation of video frame v_(1,t) may be fixed or vary in time, and the segmentation may be signaled within the data stream or not. FIG. 2 illustrates that portions 60 a and 60 b are temporally predicted using motion vectors 62 a and 62 b from a reconstructed version of any reference frame of video 14 ₁, which in the present case is exemplarily frame v_(1,t-1). As known in the art, the coding order among the frames of video 14 ₁ may not coincide with the presentation order among these frames, and accordingly the reference frame may succeed the current frame v_(1,t) in presentation time order 64. Portion 60 c is, for example, an intra predicted portion for which intra prediction parameters are inserted into data stream 18.

In encoding the depth/disparity map di t the coding branch 22 _(d,i) may exploit the above-mentioned possibilities in one or more of the below manners exemplified in the following with respect to FIG. 2.

For example, in encoding the depth/disparity map d_(1,t), coding branch 22 _(d,1) may adopt the segmentation of video frame v_(1,t) as used by coding branch 22 _(v,1). Accordingly, if there are segmentation parameters within the coding parameters for video frame v_(1,t), the retransmission thereof for depth/disparity map data d_(1,t) may be avoided. Alternatively, coding branch 22 _(d,1) may use the segmentation of video frame v_(1,t), as a basis/prediction for the segmentation to be used for depth/disparity map d_(1,t) with signalling the deviation of the segmentation relative to video frame v_(1,t) via the data stream 18. FIG. 2 illustrates the case that the coding branch 22 _(d,1) uses the segmentation of video frame v₁ as a pre-segmentation of depth/disparity map d_(1,t). That is, coding branch 22 _(d,1) adopts the pre-segmentation from the segmentation of video v_(1,t) or predicts the pre-segmentation therefrom.

Further, coding branch 22 _(d,1) may adopt or predict the coding modes of the portions 66 a, 66 b and 66 c of the depth/disparity map d_(1,t) from the coding modes assigned to the respective portion 60 a, 60 b and 60 c in video frame v_(1,t). In case of a differing segmentation between video frame v_(1,t) and depth/disparity map d_(1,t), the adoption/prediction of coding modes from video frame v_(1,t), may be controlled such that the adoption/prediction is obtained from co-located portions of the segmentation of the video frame v_(1,t). An appropriate definition of co-location could be as follows. The co-located portion in video frame v_(1,t) for a current portion in depth/disparity map d_(1,t), may, for example, be the one comprising the co-located position at the upper left corner of the current frame in the depth/disparity map d_(1,t). In case of prediction of the coding modes, coding branch 22,1,1 may signal the coding mode deviations of the portions 66 a to 66 c of the depth/disparity map d_(1,t) relative to the coding modes within video frame v_(1,t) explicitly signalled within the data stream 18.

As far as the prediction parameters are concerned, the coding branch 22 _(d,1) has the freedom to spatially adopt or predict prediction parameters used to encode neighbouring portions within the same depth/disparity map d_(1,t) or to adopt/predict same from prediction parameters used to encode co-located portions 60 a to 6 c of video frame v_(1,t). For example, FIG. 2 illustrates that portion 66 a of depth/disparity map d_(1,t) is an inter predicted portion, and the corresponding motion vector 68 a may be adopted or predicted from the motion vector 62 a of the co-located portion 60 a of video frame v_(1,t). In case of prediction, merely the motion vector difference is to be inserted into the data stream 18 as part of inter prediction parameters 48 ₂.

In terms of coding efficiency, it might be favourable for the coding branch 22 _(d,i) to have the ability to subdivide segments of the pre-segmentation of the depth/disparity map d_(1,t) using a so called wedgelet separation line 70 with signalling the location of this wedgelet separation line 70 to the decoding side within data stream 18. By this measure, in the example of FIG. 2, the portion 66 c of depth/disparity map d_(1,t) is subdivided into two wedgelet-shaped portions 72 a and 72 b. Coding branch 22 _(d,1) may be configured to encode these sub-segments 72 a and 72 b separately. In the case of FIG. 2, both sub-segments 72 a and 72 b are exemplarily inter predicted using respective motion vectors 68 c and 68 d. In case of using intra prediction for both sub-segments 72 a and 72 b, a DC value for each segment may be derived by extrapolation of the DC values of neighbouring causal segments with the option of refining each of these derived DC values by transmitting a corresponding refinement DC value to the decoder as an intra prediction parameter. Several possibilities exist in order to enable the decoder to determined the wedgelet separation lines having been used be the encoder to sub-subdivide the pre-segmentation of the depth/disparity map. The coding branch 22 _(d,1) may be configured to use any of these possibilities exclusively. Alternatively, the coding branch 22 _(d,1) may have the freedom to choose between the following coding options, and to signal the choice to the decoder as side information within the data stream 18:

-   -   The wedgelet separation line 70 may, for example, be a straight         line. The signaling of the location of this line 70 to the         decoding side may involve the signaling of one intersection         point along the border of segment 66 c along with a slope or         gradient information or the indication of the two intersection         points of the wedgelet separation line 70 with the border of         segment 66 c. In an embodiment, the wedgelet separation line 70         may be signaled explicitly within the data stream by indication         of the two intersection points of the wedgelet separation line         70 with the border of segment 66 c, where the granularity of the         grid indicating possible intersection points, i.e. the         granularity or resolution of the indication of the intersection         points, may depend on the size of the segment 66 c or coding         parameters like, e.g., the quantization parameter.     -   In an alternative embodiment, where the pre-segmentation is         given by, e.g., a quadtree-based block partitioning using dyadic         square blocks, the permissible set of intersection points for         each block size may be given as a look-up table (LUT) such that         the signaling of each intersection point involves the signaling         of a corresponding LUT index.     -   In accordance with even another possibility, however, the coding         branch 22 _(d,1) uses the reconstructed portion 60 c of the         video frame V|in the decoded picture buffer 34 in order to         predict the location of the wedgelet separation line 70 with         signaling within the data stream, if ever, a deviation of the         wedgelet separation line 70 actually to be used in encoding         segment 66 c, to the decoder. In particular, module 52 may         perform an edge detection on the video v_(1,t) at a location         corresponding to the location of portion 66 c in depth/disparity         map d_(1,t). For example, the detection may be sensitive to         edges in the video frame v_(1,t) where the spatial gradient of         some interval scaled feature such as the brightness, the luma         component or a chroma component or chrominance or the like,         exceeds some minimum threshold. Based on the location of this         edge 72, module 52 could determine the wedgelet separation line         70 such that same extends along edge 72. As the decoder also has         access to the reconstructed video frame v_(1,t), the decoder is         able to likewise determine the wedgelet separation line 70 so as         to subdivide portion 66 c into wedgelet-shaped sub-portions 72 a         and 72 b. Signaling capacity for signaling the wedgelet         separation line 70 is, therefore, saved. The aspect of having a         portion 66 c size dependent resolution for representing the         wedgelet separation line location could also apply for the         present aspect of determining the location of line 70 by edge         detection, and for transmitting the optional deviation from the         predicted location.     -   In encoding the video 14 ₂, the coding branch 22 _(v,2) has, in         addition to the coding mode options available for coding branch         22 _(v,1), the option of inter-view prediction.

FIG. 2 illustrates, for example, that a portion 64 b of the segmentation of the video frame v_(2,t) is inter-view predicted from the temporally corresponding video frame v_(1,t) of first view video 14 ₁ using a disparity vector 76.

Despite this difference, coding branch 22 _(v,2) may additionally exploit all of the information available form the encoding of video frame v_(1,t) and depth/disparity map d_(1,t) such as, in particular, the coding parameters used in these encodings. Accordingly, coding branch 22 _(v,2) may adopt or predict the motion parameters including motion vector 78 for a temporally inter predicted portion 74 a of video frame V_(2,t) from any or, or a combination of, the motion vectors 62 a and 68 a of co-located portions 60 a and 66 a of the temporally aligned video frame v_(1,t) and depth/disparity map d_(1,t) respectively. If ever, a prediction residual may be signaled with respect to the inter prediction parameters for portion 74 a. In this regard, it should be recalled that the motion vector 68 a may have already been subject to prediction/adoption from motion vector 62 a itself.

The other possibilities of adopting/predicting coding parameters for encoding video frame v_(2,t) as described above with respect to the encoding of depth/disparity map d_(1,t), are applicable to the encoding of the video frame v_(2,t) by coding branch 22 _(v,2) as well, with the available common data distributed by module 52 being, however, increased because the coding parameters of both the video frame v_(1,t) and the corresponding depth/disparity map d_(1,t) are available.

Then, coding branch 22 _(d,2) encodes the depth/disparity map d_(2,t) similarly to the encoding of the depth/disparity map d_(1,t) by coding branch 22 _(d,1). This is true, for example, with respect to all of the coding parameter adoption/prediction occasions from the video frame v_(2,t) of the same view 12 ₂. Additionally, however, coding branch 22 _(d,2) has the opportunity to also adopt/predict coding parameters from coding parameters having been used for encoding the depth/disparity map d_(1,t) of the preceding view 12 ₁. Additionally, coding branch 22 _(d,2) may use inter-view prediction as explained with respect to the coding branch 22 _(v,2).

With regard to the coding parameter adoption/prediction, it may be worthwhile to restrict the possibility of the coding branch 22 _(d,2) to adopt/predict its coding parameters from the coding parameters of previously coded entities of the multi-view signal 10 to the video 14 ₂ of the same view 12 ₂ and the depth/disparity map data 16 ₁ of the neighboring, previously coded view 12 ₁ in order to reduce the signaling overhead stemming from the necessity to signal to the decoding side within the data stream 18 the source of adoption/prediction for the respective portions of the depth/disparity map d_(2,t). For example, the coding branch 22 _(d,2) may predict the prediction parameters for an interview predicted portion 80 a of depth/disparity map d_(2,t) including disparity vector 82 from the disparity vector 76 of the co-located portion 74 b of video frame v_(2,t). In this case, an indication of the data entity from which the adoption/prediction is conducted, namely video 14 ₂ in the case of FIG. 2, may be omitted since video 14 ₂ is the only possible source for disparity vector adoption/prediction for depth/disparity map d_(2,t). In adopting/predicting the inter prediction parameters of a temporally inter predicted portion 80 b, however, the coding branch 22 _(d,2) may adopt/predict the corresponding motion vector 84 from anyone of motion vectors 78, 68 a and 62 a and accordingly, coding branch 22 _(d,2) may be configured to signal within the data stream 18 the source of adoption/prediction for motion vector 84. Restricting the possible sources to video 14 ₂ and depth/disparity map 16 ₁ reduces the overhead in this regard.

Regarding the separation lines, the coding branch 22 _(d,2) has the following options in addition to those already discussed above:

-   -   For coding the depth/disparity map d_(2,t) of view 12 ₂ by using         a wedgelet separation line, the corresponding         disparity-compensated portions of signal d_(1,t) can be used,         such as by edge detection and implicitly deriving the         corresponding wedgelet separation line. Disparity compensation         is then used to transfer the detected line in depth/disparity         map d_(1,t) to depth/disparity map d_(2,t). For disparity         compensation the foreground depth/disparity values along the         respective detected edge in depth/disparity map d_(1,t) may be         used.     -   Alternatively, for coding the depth/disparity map d_(2,t) of         view 12 ₂ by using a wedgelet separation line, the corresponding         disparity-compensated portions of signal d_(1,t) can be used, by         using a given wedgelet separation line in the         disparity-compensated portion of d_(1,t), i.e. using a wedgelet         separation line having been used in coding a co-located portion         of the signal di t as a predictor or adopting same.

After having described the encoder 20 of FIG. 1, it should be noted that same may be implemented in software, hardware or firmware, i.e. programmable hardware. Although the block diagram of FIG. 1 suggests that encoder 20 structurally comprises parallel coding branches, namely one coding branch per video and depth/disparity data of the multi-view signal 10, this does not need to be the case. For example, software routines, circuit portions or programmable logic portions configured to perform the tasks of elements 24 to 40, respectively, may be sequentially used to fulfill the tasks for each of the coding branches. In parallel processing, the processes of the parallel coding branches may be performed on parallel processor cores or on parallel running circuitries.

FIG. 3 shows an example for a decoder capable of decoding data stream 18 so as to reconstruct one or several view videos corresponding to the scene represented by the multi-view signal from the data stream 18. To a large extent, the structure and functionality of the decoder of FIG. 3 is similar to the encoder of FIG. 20 so that reference signs of FIG. 1 have been re-used as far as possible to indicate that the functionality description provided above with respect to FIG. 1 also applies to FIG. 3.

The decoder of FIG. 3 is generally indicated with reference sign 100 and comprises an input for the data stream 18 and an output for outputting the reconstruction of the aforementioned one or several views 102. The decoder 100 comprises a demultiplexer 104 and a pair of decoding branches 106 for each of the data entities of the multi-view signal 10 (FIG. 1) represented by the data stream 18 as well as a view extractor 108 and a coding parameter exchanger 110. As it was the case with the encoder of FIG. 1, the decoding branches 106 comprise the same decoding elements in a same interconnection, which are, accordingly, representatively described with respect to the decoding branch 106 v,i responsible for the decoding of the video 14 ₁ of the first view 12 ₁. In particular, each coding branch 106 comprises an input connected to a respective output of the multiplexer 104 and an output connected to a respective input of view extractor 108 so as to output to view extractor 108 the respective data entity of the multi-view signal 10, i.e. the video 14 ₁ in case of decoding branch 106 _(v,1). In between, each coding branch 106 comprises a dequantization/inverse-transform module 28, an adder 30, a further processing module 32 and a decoded picture buffer 34 serially connected between the multiplexer 104 and view extractor 108. Adder 30, further-processing module 32 and decoded picture buffer 34 form a loop along with a parallel connection of prediction modules 36 and 38 followed by a combiner/selector 40 which are, in the order mentioned, connected between decoded picture buffer 34 and the further input of adder 30. As indicated by using the same reference numbers as in the case of FIG. 1, the structure and functionality of elements 28 to 40 of the decoding branches 106 are similar to the corresponding elements of the coding branches in FIG. 1 in that the elements of the decoding branches 106 emulate the processing of the coding process by use of the information conveyed within the data stream 18. Naturally, the decoding branches 106 merely reverse the coding procedure with respect to the coding parameters finally chosen by the encoder 20, whereas the encoder 20 of FIG. 1 has to find an optimum set of coding parameters in some optimization sense such as coding parameters optimizing a rate/distortion cost function with, optionally, being subject to certain constraints such as maximum bit rate or the like.

The demultiplexer 104 is for distributing the data stream 18 to the various decoding branches 106. For example, the demultiplexer 104 provides the dequantization/inverse-transform module 28 with the residual data 421, the further processing module 32 with the further-processing parameters 50 ₁, the intra prediction module 36 with the intra prediction parameters 46 ₁ and the inter prediction module 38 with the inter prediction modules 48 ₁. The coding parameter exchanger 110 acts like the corresponding module 52 in FIG. 1 in order to distribute the common coding parameters and other common data among the various decoding branches 106.

The view extractor 108 receives the multi-view signal as reconstructed by the parallel decoding branches 106 and extracts therefrom one or several views 102 corresponding to the view angles or view directions prescribed by externally provided intermediate view extraction control data 112.

Due to the similar construction of the decoder 100 relative to the corresponding portion of the encoder 20, its functionality up to the interface to the view extractor 108 is easily explained analogously to the above description.

In fact, decoding branches 106 _(v,i) and 106 _(d,i) act together to reconstruct the first view 12 ₁ of the multi-view signal 10 from the data stream 18 by, according to first coding parameters contained in the data stream 18 (such as scaling parameters within 42 ₁, the parameters 46 ₁, 48 ₁, 50 ₁, and the corresponding non-adopted ones, and prediction residuals, of the coding parameters of the second branch 16 _(d,i), namely 42 ₂, parameters 46 ₂, 48 ₂, 50 ₂), predicting a current portion of the first view 12 ₁ from a previously reconstructed portion of the multi-view signal 10, reconstructed from the data stream 18 prior to the reconstruction of the current portion of the first view 12 ₁ and correcting a prediction error of the prediction of the current portion of the first view 12 ₁ using first correction data, i.e. within 42 ₁ and 42 ₂, also contained in the data stream 18. While decoding branch 106 _(v,i) is responsible for decoding the video 14 ₁, a coding branch 106 _(d,i) assumes responsibility for reconstructing the depth/disparity map data 16 ₁. See, for example, FIG. 2: The decoding branch 106 _(v,i) reconstructs the video 14 ₁ of the first view 12 ₁ from the data stream 18 by, according to corresponding coding parameters read from the data stream 18, i.e. scaling parameters within 42 ₁, the parameters 46 ₁, 48 ₁, 50 ₁, predicting a current portion of the video 14 ₁ such as 60 a, 60 b or 60 c from a previously reconstructed portion of the multi-view signal 10 and correcting a prediction error of this prediction using corresponding correction data obtained from the data stream 18, i.e. from transform coefficient levels within 42 ₁. For example, the decoding branch 106 v,i processes the video 14 ₁ in units of the segments/portions using the coding order among the video frames and, for coding the segments within the frame, a coding order among the segments of these frames as the corresponding coding branch of the encoder did. Accordingly, all previously reconstructed portions of video 14 ₁ are available for prediction for a current portion. The coding parameters for a current portion may include one or more of intra prediction parameters 50 ₁, inter prediction parameters 48 ₁, filter parameters for the further-processing module 32 and so forth. The correction data for correcting the prediction error may be represented by the spectral transform coefficient levels within residual data 42 ₁. Not all of these of coding parameters need to transmitted in full. Some of them may have been spatially predicted from coding parameters of neighboring segments of video 14 ₁. Motion vectors for video 14 ₁, for example, may be transmitted within the bitstream as motion vector differences between motion vectors of neighboring portions/segments of video 14 ₁.

As far as the second decoding branch 106 _(d,i) is concerned, same has access not only to the residual data 422 and the corresponding prediction and filter parameters as signaled within the data stream 18 and distributed to the respective decoding branch 106 _(d,i) by demultiplexer 104, i.e. the coding parameters not predicted by across inter-view boundaries, but also indirectly to the coding parameters and correction data provided via demultiplexer 104 to decoding branch 106 _(v,i) or any information derivable therefrom, as distributed via coding information exchange module 110. Thus, the decoding branch 106 _(d,i) determines its coding parameters for reconstructing the depth/disparity map data 16 ₁ from a portion of the coding parameters forwarded via demultiplexer 104 to the pair of decoding branches 106 _(v,i) and 106 _(d,i) for the first view 12 ₁, which partially overlaps the portion of these coding parameters especially dedicated and forwarded to the decoding branch 106 _(v,i). For example, decoding branch 106 _(d,i) determines motion vector 68 a from motion vector 62 a explicitly transmitted within 481, for example, as a motion vector difference to another neighboring portion of frame v_(1,t), on the on hand, and a motion vector difference explicitly transmitted within 48 ₂, on the on hand. Additionally, or alternatively, the decoding branch 106 _(d,i) may use reconstructed portions of the video 14 ₁ as described above with respect to the prediction of the wedgelet separation line to predict coding parameters for decoding depth/disparity map data 16 ₁.

To be even more precise, the decoding branch 106 _(d,i) reconstructs the depth/disparity map data 14 ₁ of the first view 12 ₁ from the data stream by use of coding parameters which are at least partially predicted from the coding parameters used by the decoding branch 106 _(v,i) (or adopted therefrom) and/or predicted from the reconstructed portions of video 14 ₁ in the decoded picture buffer 34 of the decoding branch 106 _(v,i). Prediction residuals of the coding parameters may be obtained via demultiplexer 104 from the data stream 18. Other coding parameters for decoding branch 106 _(d,i) may be transmitted within data stream 108 in full or with respect to another basis, namely referring to a coding parameter having been used for coding any of the previously reconstructed portions of depth/disparity map data 16 ₁ itself. Based on these coding parameters, the decoding branch 106 _(d,i) predicts a current portion of the depth/disparity map data 14 ₁ from a previously reconstructed portion of the depth/disparity map data 16 i, reconstructed from the data stream 18 by the decoding branch 106 _(d,i) prior to the reconstruction of the current portion of the depth/disparity map data 16 ₁, and correcting a prediction error of the prediction of the current portion of the depth/disparity map data 16 ₁ using the respective correction data 42 ₂.

Thus, the data stream 18 may comprise for a portion such as portion 66 a of the depth/disparity map data 16 ₁, the following:

an indication as to whether, or as to which part of, the coding parameters for that current portion are to be adopted or predicted from corresponding coding parameters, for example, of a co-located and time-aligned portion of video 14 ₁ (or from other video 14 ₁ specific data such as the reconstructed version thereof in order to predict the wedgelet separation line),

if so, in case of prediction, the coding parameter residual,

if not, all coding parameters for the current portion, wherein same may be signaled as prediction residuals compared to coding parameters of previously reconstructed portions of the depth/disparity map data 16 ₁

if not all coding parameters are to be predicted/adapted as mentioned above, a remaining part of the coding parameters for the current portion, wherein same may be signaled as prediction residuals compared to coding parameters of previously reconstructed portions of the depth/disparity map data 16 ₁.

For example, if the current portion is an inter predicted portion such as portion 66 a, the motion vector 68 a may be signaled within the data stream 18 as being adopted or predicted from motion vector 62 a. Further, decoding branch 106 _(d,i) may predict the location of the wedgelet separation line 70 depending on detected edges 72 in the reconstructed portions of video 14 ₁ as described above and apply this wedgelet separation line either without any signalization within the data stream 18 or depending on a respective application signalization within the data stream 18. In other words, the appliance of the wedgelet separation line prediction for a current frame may be suppressed or allowed by way of signalization within the data stream 18. In even other words, the decoding branch 106 _(d,i) may effectively predict the circumference of the currently reconstructed portion of the depth/disparity map data.

The functionality of the pair of decoding branches 106 _(v,2) and 106 _(d,2) for the second view 12 ₂ is, as already described above with respect to encoding, similar as for the first view 12 ₁. Both branches cooperate to reconstruct the second view 12 ₂ of the multi-view signal 10 from the data stream 18 by use of own coding parameters. Merely that part of these coding parameters needs to be transmitted and distributed via demultiplexer 104 to any of these two decoding branches 106 _(v,2) and 106 _(d,2), which is not adopted/predicted across the view boundary between views 14 ₁ and 14 ₂, and, optionally, a residual of the inter-view predicted part. Current portions of the second view 12 ₂ are predicted from previously reconstructed portions of the multi-view signal 10, reconstructed from the data stream 18 by any of the decoding branches 106 prior to the reconstruction of the respective current portions of the second view 12 ₂, and correcting the prediction error accordingly using the correction data, i.e. 42 ₃ and 42 ₄, forwarded by the demultiplexer 104 to this pair of decoding branches 106 _(v,2) and 106 _(d,2).

The decoding branch 106 _(v,2) is configured to at least partially adopt or predict its coding parameters from the coding parameters used by any of the decoding branches 106 _(v,i) and 106 _(d,i). The following information on coding parameters may be present for a current portion of the video 14 ₂:

an indication as to whether, or as to which part of, the coding parameters for that current portion are to be adopted or predicted from corresponding coding parameters, for example, of a co-located and time-aligned portion of video 14 ₁ or depth/disparity data 16 ₁,

if so, in case of prediction, the coding parameter residual,

if not, all coding parameters for the current portion, wherein same may be signaled as prediction residuals compared to coding parameters of previously reconstructed portions of the video 14 ₂

if not all coding parameters are to be predicted/adapted as mentioned above, a remaining part of the coding parameters for the current portion, wherein same may be signaled as prediction residuals compared to coding parameters of previously reconstructed portions of the video 14 ₂.

a signalization within the data stream 18 may signalize for a current portion 74 a whether the corresponding coding parameters for that portion, such as motion vector 78, is to be read from the data stream completely anew, spatially predicted or predicted from a motion vector of a co-located portion of the video 14 ₁ or depth/disparity map data 16 ₁ of the first view 12 ₁ and the decoding branch 106 _(v,2) may act accordingly, i.e. by extracting motion vector 78 from the data stream 18 in full, adopting or predicting same with, in the latter case, extracting prediction error data regarding the coding parameters for the current portion 74 a from the data stream 18.

Decoding branch 106 _(d,2) may act similarly. That is, the decoding branch 106 _(d,2) may determine its coding parameters at last partially by adoption/prediction from coding parameters used by any of decoding branches 106 _(v,i), 106 _(d,i) and 106 _(v,2), from the reconstructed video 14 ₂ and/or from the reconstructed depth/disparity map data 16 ₁ of the first view 12 ₁. For example, the data stream 18 may signal for a current portion 80 b of the depth/disparity map data 16 ₂ as to whether, and as to which part of, the coding parameters for this current portion 80 b is to be adopted or predicted from a co-located portion of any of the video 14 ₁, depth/disparity map data 16 ₁ and video 14 ₂ or a proper subset thereof. The part of interest of these coding parameters may involve, for example, a motion vector such as 84, or a disparity vector such as disparity vector 82. Further, other coding parameters, such as regarding the wedgelet separation lines, may be derived by decoding branch 106 _(d,2) by use of edge detection within video 14 ₂. Alternatively, edge detection may even be applied to the reconstructed depth/disparity map data 16 ₁ with applying a predetermined re-projection in order to transfer the location of the detected edge in the depth/disparity map d_(1,t) to the depth/disparity map d_(2,t) in order to serve as a basis for a prediction of the location of a wedgelet separation line.

In any case, the reconstructed portions of the multi-view data 10 arrive at the view extractor 108 where the views contained therein are the basis for a view extraction of new views, i.e. the videos associated with these new views, for example. This view extraction may comprise or involve a re-projection of the videos 14 ₁ and 14 ₂ by using the depth/disparity map data associated therewith. Frankly speaking, in re-projecting a video into another intermediate view, portions of the video corresponding to scene portions positioned nearer to the viewer are shifted along the disparity direction, i.e. the direction of the viewing direction difference vector, more than portions of the video corresponding to scene portions located farther away from the viewer position. An example for the view extraction performed by view extractor 108 is outlined below with respect to FIGS. 4-6 and 8. Disocclusion handling may be performed by view extractor as well.

However, before describing further embodiments below, it should be noted that several amendments may be performed with respect to the embodiments outlined above. For example, the multi-view signal 10 does not have to necessarily comprise the depth/disparity map data for each view. It is even possible that none of the views of the multi-view signal 10 has a depth/disparity map data associated therewith. Nevertheless, the coding parameter reuse and sharing among the multiple views as outlined above yields a coding efficiency increase. Further, for some views, the depth/disparity map data may be restricted to be transmitted within the data stream to disocclusion areas, i.e. areas which are to fill disoccluded areas in re-projected views from other views of the multi-vie signal with being set to a don't care value in the remaining areas of the maps.

As already noted above, the views 12 ₁ and 12 ₂ of the multi-view signal 10 may have different spatial resolutions. That is, they may be transmitted within the data stream 18 using different resolutions. In even other words, the spatial resolution at which coding branches 22 _(v,i) and 22 _(d,i) perform the predictive coding may be higher than the spatial resolution at which coding branches 22 _(v,2) and 22 _(d,2) perform the predictive coding of the subsequent view 12 ₂ following view 12 ₁ in the above-mentioned order among the views. The inventors of the present invention found out that this measure additionally improves the rate/distortion ratio when considering the quality of the synthesized views 102. For example, the encoder of FIG. 1 could receive view 12 ₁ and view 12 ₂ initially at the same spatial resolution with then, however, down-sampling the video 14 ₂ and the depth/disparity map data 16 ₂ of the second view 12 ₂ to a lower spatial resolution prior to subjecting same to the predictive encoding procedure realized by modules 24 to 40. Nevertheless, the above-mentioned measures of adoption and prediction of coding parameters across view boundaries could still be performed by scaling the coding parameters forming the basis of adoption or prediction according to the ratio between the different resolutions of source and destination view. See, for example, FIG. 2. If coding branch 22 _(v,2) intends to adopt or predict motion vector 78 from any of motion vector 62 a and 68 a, then coding branch 22 _(v,2) would down-scale them by a value corresponding to the ratio between the high spatial resolution of view 12 i, i.e. the source view, and the low spatial resolution of view 12 ₂, i.e. the destination view. Naturally, the same applies with regard to the decoder and the decoding branches 106. Decoding branches 106 _(v,2) and 106 _(d,2) would perform the predictive decoding at the lower spatial resolution relative to decoding branches 106 _(v,i) and 106 _(d,i). After reconstruction, up-sampling would be used in order to transfer the reconstructed pictures and depth/disparity maps output by the decoding picture buffers 34 of decoding branches 106 _(v,2) and 106 _(d,2) from the lower spatial resolution to the higher spatial resolution before the latter reach view extractor 108. A respective up-sampler would be positioned between the respective decoded picture buffer and the respective input of view extractor 108. As mentioned above, within one view 12 ₁ or 12 ₂, video and associated depth/disparity map data may have the same spatial resolution. However, additionally or alternatively, these pairs have different spatial resolution and the measures described just above are performed across spatial resolution boundaries, i.e. between depth/disparity map data and video. Further, according to another embodiment, there would be three views including view 12 ₃, not shown in FIGS. 1 to 3 for illustration purposes, and while the first and second views would have the same spatial resolution, the third view 12 ₃ would have the lower spatial resolution. Thus, according to the just-described embodiments, some subsequent views, such as view 12 ₂, are down-sampled before encoding and up-sampled after decoding. This sub- and up-sampling, respectively, represents a kind of pre- or postprocessing of the de/coding branches, wherein the coding parameters used for adoption/prediction of coding parameters of any subsequent (destination) view are scaled according to the respective ratio of the spatial resolutions of the source and destination views. As already mentioned above, the lower quality at which these subsequent views, such as view 12 ₂, are transmitted and predictively coded, does not significantly affect the quality of the intermediate view output 102 of intermediate view extractor 108 due to the processing within intermediate view extractor 108. View extractor 108 performs a kind of interpolation/lowpass filtering on the videos 14 ₁ and 14 ₂ anyway due to the re-projection into the intermediate view(s) and the necessitated re-sampling of the re-projected video sample values onto the sample grid of the intermediate view(s). In order to exploit the fact that the first view 12 ₁ has been transmitted at an increased spatial resolution relative to the neighboring view 12 ₂, the intermediate views therebetween may be primarily obtained from view 12 ₁, using the low spatial resolution view 12 ₂ and its video 14 ₂ merely as a subsidiary view such as, for example, merely for filling the disocclusion areas of the re-projected version of video 14 ₁, or merely participating at a reduced weighting factor when performing some averaging between re-projected version of videos of view 12 ₁ on the one hand and 12 ₂ on the other hand. By this measure, the lower spatial resolution of view 12 ₂ is compensated for although the coding rate of the second view 12 ₂ has been significantly reduced due to the transmission at the lower spatial resolution.

It should also be mentioned that the embodiments may be modified in terms of the internal structure of the coding/decoding branches. For example, the intra-prediction modes may not be present, i.e. no spatial prediction modes may be available. Similarly, any of interview and temporal prediction modes may be left away. Moreover, all of the further processing options are optional. On the other hand, out-of-loop postprocessing modules maybe present at the outputs of decoding branches 106 in order to, for example, perform adaptive filtering or other quality enhancing measures and/or the above-mentioned up-sampling. Further, no transformation of the residual may be performed. Rather, the residual may be transmitted in the spatial domain rather than the frequency domain. In a more general sense, the hybrid coding/decoding designs shown in FIGS. 1 and 3 may be replaced by other coding/decoding concepts such as wavelet transform based ones.

It should also be mentioned that the decoder does not necessarily comprise the view extractor 108. Rather, view extractor 108 may not be present. In this case, the decoder 100 is merely for reconstructing any of the views 12 ₁ and 12 ₂, such as one, several or all of them. In case no depth/disparity data is present for the individual views 12 ₁ and 12 ₂, a view extractor 108 may, nevertheless, perform an intermediate view extraction by exploiting the disparity vectors relating corresponding portions of neighboring views to each other. Using these disparity vectors as supporting disparity vectors of a disparity vector field associated with videos of neighboring views, the view extractor 108 may build an intermediate view video from such videos of neighboring views 12 ₁ and 12 ₂ by applying this disparity vector field. Imagine, for example, that video frame V_(2,t) had 50% of its portions/segments interview predicted. That is, for 50% of the portions/segments, disparity vectors would exist. For the remaining portions, disparity vectors could be determined by the view extractor 108 by way of interpolation/extrapolation in the spatial sense. Temporal interpolation using disparity vectors for portions/segments of previously reconstructed frames of video 14 ₂ may also be used. Video frame v_(2,t) and/or reference video frame v_(1,t), may then be distorted according to these disparity vectors in order to yield an intermediate view. To this end, the disparity vectors are scaled in accordance with the intermediate view position of the intermediate view between view positions of the first view 12 ₁ and a second view 12 ₂. Details regarding this procedure are outlined in more detail below.

A coding efficiency gain is obtained by using the above-mentioned option of determining wedgelet separation lines so as to extend along detected edges in a reconstructed current frame of the video. Thus, as explained above the wedeglet separation line position prediction described above may be used for each of the views, i.e. all of them or merely a proper subset thereof.

Insofar, the above discussion of FIG. 3 also reveals a decoder having a decoding branch 106 _(c,i) configured to reconstruct a current frame v_(1,t) of a video 14 ₁ from a data stream 18, and a decoding branch 106 _(d,i) configured to detect an edge 72 in the reconstructed current frame v_(1,t) determine a wedgelet separation line 70 so as to extend along the edge 72, and reconstruct a depth/disparity map d_(1,t) associated with the current frame v_(1,t) in units of segments 66 a, 66 b, 72 a, 72 b of a segmentation of the depth/disparity map d_(1,t) in which two neighboring segments 72 a, 72 b of the segmentation are separated from each other by the wedgelet separation line 70, from the data stream 18. The decoder may be configured to predict the depth/disparity map d_(1,t) segment-wise using distinct sets of prediction parameters for the segments, from previously reconstructed segments of the depth/disparity map d_(1,t) associated with the current frame v_(1,t), or a depth/disparity map di t-i associated with any of the previously decoded frames v_(t-1) of the video. The decoder may be configured such that the wedgelet separation line 70 is a straight line and the decoder is configured to determine the segmentation from a block based pre-segmentation of the depth/disparity map d_(1,t) by dividing a block 66 c of the pre-segmentation along the wedgelet separation line 70 so that the two neighboring segments 72 a, 72 b are wedgelet-shaped segments together forming the block 66 c of the pre-segmentation.

Summarizing some of the above embodiments, these embodiments enable view extraction from commonly decoding multi-view video and supplementary data. The term “supplementary data” is used in the following in order to denote depth/disparity map data. According to these embodiments, the multi-view video and the supplementary data is embedded in one compressed representation. The supplementary data may consist of per-pixel depth maps, disparity data or 3D wire frames. The extracted views 102 can be different from the views 12 ₁, 12 ₂ contained in the compressed representation or bitstream 18 in terms of view number and spatial position. The compressed representation 18 has been generated before by an encoder 20, which might use the supplementary data to also improve the coding of the video data.

In contrast to current state-of-the-art methods, a joint decoding is carried out, where the decoding of video and supplementary data may be supported and controlled by common information. Examples are a common set of motion or disparity vectors, which is used to decode the video as well as the supplementary data. Finally, views are extracted from the decoded video data, supplementary data and possible combined data, where the number and position of extracted views is controlled by an extraction control at the receiving device.

Further, the multi-view compression concept described above is useable in connection with disparity-based view synthesis. Disparity-based view synthesis means the following. If scene content is captured with multiple cameras, such as the videos 14 ₁ and 14 ₂, a 3D perception of this content can be presented to the viewer. For this, stereo pairs have to be provided with slightly different viewing direction for the left and right eye. The shift of the same content in both views for equal time instances is represented by the disparity vector. Similar to this, the content shift within a sequence between different time instances is the motion vector, as shown in FIG. 4 for two views at two time instances.

Usually, disparity is estimated directly or as scene depth, provided externally or recorded with special sensors or cameras. Motion estimation is already carried out by a standard coder. If multiple views are coded together, the temporal and inter-view direction are treated similarly, such that motion estimation is carried out in temporal as well as interview direction during encoding. This has already been described above with respect to FIGS. 1 and 2. The estimated motion vectors in inter-view direction are the disparity vectors. Such disparity vectors were shown in FIG. 2 exemplarily at 82 and 76. Therefore, encoder 20 also carries out disparity estimation implicitly and the disparity vectors are included in the coded bitstream 18. These vectors can be used for additional intermediate view synthesis at the decoder, namely within view extractor 108.

Consider a pixel p₁(x₁,y₁) in view 1 at position (x₁,y₁) and a pixel p₂(x₂,y₂) in view 2 at position (x₂,y₂), which have identical luminance values. Then,

p ₁(x ₁ ,y ₁)=p ₂(x ₂ ,y ₂).  (1)

Their positions (x₁,y₁) and (X₂,y₂) are connected by the 2D disparity vector, e.g. from view 2 to view 1, which is d₂₁(x₂,y₂) with components d_(x,21)(x₂,y₂) and d_(y,21)(x₂,y₂). Thus, the following equation holds:

(x ₁ ,y ₁)=(x ₂ +d _(X,21)(x ₂ ,y ₂),y ₂ +d _(y,21)(x ₂ ,y ₂)).  (2)

Combining (1) and (2),

P ₁(x ₂ +d _(x,21)(x ₂ ,y ₂),y ₂ +d _(y,21)(x ₂ ,y ₂))=p ₂(x ₂ ,y ₂).  (3)

As shown in FIG. 5, bottom right, two points with identical content can be connected with a disparity vector: Adding this vector to the coordinates of p₂, gives the position of pi in image coordinates. If the disparity vector d₂₁(x₂,y₂) is now scaled by a factor K=[0 . . . 1], any intermediate position between (x₁,y₁) and (x₂,y₂) can be addressed. Therefore, intermediate views can be generated by shifting the image content of view 1 and/or view 2 by scaled disparity vectors. An example is shown in FIG. 6 for an intermediate view.

Therefore, new intermediate views can be generated with any position between view 1 and view 2.

Beyond this, also view extrapolation can also be achieved by using scaling factors K<0 and K>1 for the disparities.

These scaling methods can also be applied in temporal direction, such that new frames can be extracted by scaling the motion vectors, which leads to the generation of higher frame rate video sequences.

Now, returning to the embodiments described above with respect to FIGS. 1 and 3, these embodiments described, inter alia, a parallel decoding structure with decoders for video and supplementary data such as depth maps, that contain a common information module, namely module 110. This module uses spatial information from both signals that was generated by an encoder. Examples for common are one set of motion or disparity vectors, e.g. extracted in the video data encoding process, which is also used for depth data, for example. At the decoder, this common information is used for steering the decoding video and depth data and providing the necessitated information to each decoder branch as well as, optionally, for extracting new views. With this information, all necessitated views, e.g. for an N-view display, can be extracted in parallel from the video data. Examples for common information or coding parameters to be shared among the individual coding/decoding branches are:

-   -   Common motion and disparity vectors, e.g. from the video data         that is also used for the supplementary data     -   Common block partitioning structure, e.g. from the video data         partitioning that is also used for the supplementary data     -   Prediction modes     -   Edge and contour data in luminance and/or chrominance         information, e.g. a straight line in a luminance block. This is         used for supplementary data non-rectangular block partitioning.         This partitioning is called wedgelet and separates a block into         two regions by a straight line with certain angle and position

The common information may also be used as a predictor from one decoding branch (e.g. for video) to be refined in the other branch (e.g. supplementary data) and vice versa. This may include e.g. refinement of motion or disparity vectors, initialization of block structure in supplementary data by the block structure of video data, extracting a straight line from the luminance or chrominance edge or contour information from a video block and using this line for a wedgelet separation line prediction (with same angle but possibly different position in the corresponding depth block keeping the angle. The common information module also transfers partially reconstructed data from one decoding branch to the other. Finally, data from this module may also be handed to the view extraction module, where all necessitated views, e.g. for a display are extracted (displays can be 2D, stereoscopic with two views, autostereoscopic with N views).

One important aspect is that if more than one single pair of view and depth/supplementary signal is encoded/decoded by using the above described en/decoding structure, an application scenario may be considered where we have to transmit for each time instant t a pair of color views _(vColor) _(_)1(t), v_(Color) _(_)2(t) together with the corresponding depth data v_(Depth) _(_)1(t) and v_(Depth) _(_)2(f). The above embodiments suggest encoding/decoding first the signal v_(Color) _(_)1(t), e.g., by using conventional motion-compensated prediction. Then, in a second step, for encoding/decoding of the corresponding depth signal v_(Depth) _(_)1(f) information from the encoded/decoded signal v_(Color) _(_)1(t) can be reused, as outlined above. Subsequently, the accumulated information from v_(Color) _(_)1(t) and v_(Depth) _(_)1(t) can be further utilized for encoding/decoding of v_(Color) _(_)2(t) and/or v_(Depth) _(_)2(t). Thus, by sharing and reusing common information between the different views and/or depths redundancies can be exploited to a large extent.

The decoding and view extraction structure of FIG. 3 may alternatively be illustrated as shown in FIG. 7.

As shown, the structure of the decoder of FIG. 7 is based on two parallelized classical video decoding structures for color and supplementary data. In addition, it contains a Common Information Module. This module can send, process and receive any shared information from and to any module of both decoding structures. The decoded video and supplementary data are finally combined in the View Extraction Module in order to extract the necessitated number of views. Here, also common information from the new module may be used. The new modules of the newly proposed decoding and view extraction method are highlighted by the gray box in FIG. 7.

The decoding process starts with receiving a common compressed representation or bit stream, which contains video data, supplementary data as well as information, common to both, e.g. motion or disparity vectors, control information, block partitioning information, prediction modes, contour data, etc. from one or more views.

First, an entropy decoding is applied to the bit stream to extract the quantized transform coefficients for video and supplementary data, which are fed into the two separate coding branches, highlighted by the doted grey boxes in FIG. 7, labeled “Video Data processing” and “Supplementary Data Processing”. Furthermore, the entropy decoding also extracts shared or common data and feeds it into the new Common Information Module.

Both decoding branches operate similar after entropy decoding. The received quantized transform coefficients are scaled and an inverse transform is applied to obtain the difference signal. To this, previously decoded data from temporal or neighboring views is added. The type of information to be added is controlled by special control data: In the case of intra coded video or supplementary data, no previous or neighboring information is available, such that intra frame reconstruction is applied. For inter coded video or supplementary data, previously decoded data from temporally preceding or neighboring views is available (current switch setting in FIG. 7). The previously decoded data is shifted by the associated motion vectors in the motion compensation block and added to the difference signal to generate initial frames. If the previously decoded data belongs to a neighboring view, the motion data represents the disparity data. These initial frames or views are further processed by deblocking filters and possibly enhancement methods, e.g. edge smoothing, etc. to improve the visual quality.

After this improvement stage, the reconstructed data is transferred to the decoded picture buffer. This buffer orders the decoded data and outputs the decoded pictures in the correct temporal order for each time instance. The stored data is also used for the next processing cycle to serve as input to the scalable motion/disparity compensation.

In addition to this separate video and supplementary decoding, the new Common Information Module is used, which processes any data, which is common to video and supplementary data. Examples of common information include shared motion/disparity vectors, block partitioning information, prediction modes, contour data, control data, but also common transformation coefficients or modes, view enhancement data, etc. Any data, which is processed in the individual video and supplementary modules, may also be part of the common module. Therefore, connections to and from the common module to all parts of the individual decoding branches may exist. Also, the common information module may contain enough data, that only one separate decoding branch and the common module are necessitated in order to decoded all video and supplementary data. An example for this is a compressed representation, where some parts only contain video data and all other parts contain common video and supplementary data. Here, the video data is decoded in the video decoding branch, while all supplementary data is processed in the common module and output to the view synthesis. Thus, in this example, the separate supplementary branch is not used. Also, individual data from modules of the separate decoding branches may send information back to the Common Information Processing module, e.g. in the form of partially decoded data, to be used there or transferred to the other decoding branch. An example is decoded video data, like transform coefficients, motion vectors, modes or settings, which are transferred to the appropriate supplementary decoding modules.

After decoding, the reconstructed video and supplementary data are transferred to the view extraction either from the separate decoding branches or from the Common Information Module. In the View Extraction Module, such as 110 in FIG. 3, the necessitated views for a receiving device, e.g. multi-view display, are extracted. This process is controlled by the intermediate view extraction control, which sets the necessitated number and position of view sequences. An example for view extraction is view synthesis: If a new view is to be synthesized between two original views 1 and 2, as shown in FIG. 6, data from view 1 may be shifted to the new position first. This disparity shift however is different for foreground and background objects, as the shift is inverse proportional to the original scene depth (frontal distance from the camera). Therefore, new background areas become visible in the synthesized view, which were not visible in view 1. Here, view 2 can be used to fill this information. Also, spatially neighboring data may be used, e.g. adjacent background information.

As an example, consider the setting in FIG. 8. Here, the decoded data consists of 2 view sequences with color data v_(Color) 1 and v_(Color) 2, as well as depth data v_(Depth) 1 and v_(Depth) 2. From this data, views for a 9 view display with views v_(D) 1, v_(D) 2, . . . , v_(D) 9 shall be extracted. The display signals the number and spatial position of views via the intermediate view extraction control. Here, 9 views are necessitated with a spatial distance of 0.25, such that neighboring display views (e.g. v_(D) 2 and v_(D) 3) are 4 times closer together in terms of spatial position and stereoscopic perception than the views in the bit stream. Therefore, the set of view extraction factors {k₁, k₂, . . . , k₉} is set to {−0.5, −0.25, 0, 0.25, 0.5, 0.75, 1, 1.25, 1.5}. This indicates that the decoded color views v_(Color) 1 and v_(Color) 2 coincident in their spatial position with the display views v_(D) 3 and v_(D) 7 (as k₃=0 and k₇=1). Furthermore, v_(D) 3, v_(D) 4 and v_(D) 5 are interpolated between v_(Color) 1 and v_(Color) 2. Finally, v_(D) 1 and v_(D) 2 as well as v_(D) 8 and v_(D) 9 are extrapolated at each side of the bit stream pair v_(Color) 1, v_(Color) 2. With the set of view extraction factors, the depth data v_(Depth) 1 and v_(Depth) 2 is transformed into per pixel displacement information and scaled accordingly in the view extraction stage in order to obtain 9 differently shifted versions of the decoded color data.

Although some aspects have been described in the context of an apparatus, it is clear that these aspects also represent a description of the corresponding method, where a block or device corresponds to a method step or a feature of a method step. Analogously, aspects described in the context of a method step also represent a description of a corresponding block or item or feature of a corresponding apparatus. Some or all of the method steps may be executed by (or using) a hardware apparatus, like for example, a microprocessor, a programmable computer or an electronic circuit. In some embodiments, some one or more of the most important method steps may be executed by such an apparatus.

The inventive encoded multi-view signal can be stored on a digital storage medium or can be transmitted on a transmission medium such as a wireless transmission medium or a wired transmission medium such as the Internet.

Depending on certain implementation requirements, embodiments of the invention can be implemented in hardware or in software. The implementation can be performed using a digital storage medium, for example a floppy disk, a DVD, a Blu-Ray, a CD, a ROM, a PROM, an EPROM, an EEPROM or a FLASH memory, having electronically readable control signals stored thereon, which cooperate (or are capable of cooperating) with a programmable computer system such that the respective method is performed. Therefore, the digital storage medium may be computer readable.

Some embodiments according to the invention comprise a data carrier having electronically readable control signals, which are capable of cooperating with a programmable computer system, such that one of the methods described herein is performed.

Generally, embodiments of the present invention can be implemented as a computer program product with a program code, the program code being operative for performing one of the methods when the computer program product runs on a computer. The program code may for example be stored on a machine readable carrier.

Other embodiments comprise the computer program for performing one of the methods described herein, stored on a machine readable carrier.

In other words, an embodiment of the inventive method is, therefore, a computer program having a program code for performing one of the methods described herein, when the computer program runs on a computer.

A further embodiment of the inventive methods is, therefore, a data carrier (or a digital storage medium, or a computer-readable medium) comprising, recorded thereon, the computer program for performing one of the methods described herein. The data carrier, the digital storage medium or the recorded medium are typically tangible and/or non-transitionary.

A further embodiment of the inventive method is, therefore, a data stream or a sequence of signals representing the computer program for performing one of the methods described herein. The data stream or the sequence of signals may for example be configured to be transferred via a data communication connection, for example via the Internet.

A further embodiment comprises a processing means, for example a computer, or a programmable logic device, configured to or adapted to perform one of the methods described herein.

A further embodiment comprises a computer having installed thereon the computer program for performing one of the methods described herein.

A further embodiment according to the invention comprises an apparatus or a system configured to transfer (for example, electronically or optically) a computer program for performing one of the methods described herein to a receiver. The receiver may, for example, be a computer, a mobile device, a memory device or the like. The apparatus or system may, for example, comprise a file server for transferring the computer program to the receiver.

In some embodiments, a programmable logic device (for example a field programmable gate array) may be used to perform some or all of the functionalities of the methods described herein. In some embodiments, a field programmable gate array may cooperate with a microprocessor in order to perform one of the methods described herein. Generally, the methods are advantageously performed by any hardware apparatus.

While this invention has been described in terms of several embodiments, there are alterations, permutations, and equivalents which will be apparent to others skilled in the art and which fall within the scope of this invention. It should also be noted that there are many alternative ways of implementing the methods and compositions of the present invention. It is therefore intended that the following appended claims be interpreted as including all such alterations, permutations, and equivalents as fall within the true spirit and scope of the present invention. 

What is claimed:
 1. A decoder for decoding an encoded video data stream to generate a multi-view video, the decoder comprising: a view decoder configured for: extracting, from a data stream using a processor, first information associated with a first coding block in a first view of a multi-view video signal, wherein the first information is indicative of whether a motion parameter of the first coding block is to (a) be read from the data stream independent of another coding parameter, or (b) reuse one or more coding parameters of a second coding block located in a second view of the multi-view video signal; if the first information indicates that the motion parameter of the first coding block is to be read from the data stream independent of another coding parameter, extracting, using the processor, the motion parameter of the first coding block from the data stream; if the first information indicates that the motion parameter of the first coding block is to reuse the one or more coding parameters from the second coding block in the second view: receiving, using the processor, the one or more coding parameters including a motion parameter of the second coding block, predicting, using the processor, the motion parameter of the first coding block based on the motion parameter of the second coding block, and extracting prediction error data associated with the motion parameter of the first coding block; generating, using the processor, a prediction of the first coding block based on (i) the extracted or predicted motion parameter of the first coding block, and (ii) the prediction error data if the first information indicates that the motion parameter of the first coding block is to reuse the one or more coding parameters; obtaining, from the data stream using the processor, residual data associated with the first coding block; and reconstructing, using the processor, the first coding block using the prediction of the first coding block and the residual data to produce a part of a video frame in the first view of the multi-view video.
 2. The decoder of claim 1, wherein each of the first and second views comprises different types of information components.
 3. The decoder of claim 2, wherein the different types of information components include a video and a depth map corresponding to the video.
 4. The decoder of claim 3, wherein the first coding block comprises video data and is reconstructed based on a first subset of the one or more coding parameters from the second coding block.
 5. The decoder of claim 4, wherein the first coding block comprises depth data and is reconstructed based on a second subset of the one or more coding parameters from the second coding block.
 6. The decoder of claim 3, wherein the view decoder is further configured for: reconstructing a first depth coding block in the first view based on a first edge associated with the first depth coding block, the decoder further comprising another view decoder configured for: predicting a second edge associated with a second depth coding block of the second view based on the first edge; and reconstructing the second depth coding block of the second view based on the second edge.
 7. The decoder of claim 1, wherein the first coding block is reconstructed in accordance with a first spatial resolution and the second coding block is reconstructed in accordance with a second spatial resolution.
 8. The decoder of claim 1, wherein the decoder is further configured to generate an intermediate coding block based on the first and the second coding blocks.
 9. The decoder of claim 1, wherein the decoder is further configured to generate an intermediate view based on the first and second views.
 10. The decoder of claim 1, wherein the first information is further indicative of whether a motion parameter of the first coding block is to be predicted from a motion parameter of a previously-reconstructed portion of the first view, and if so, the view decoder is configured for: obtaining, using the processor, the motion parameter of the previously-reconstructed portion, and predicting, using the processor, the motion parameter of the first coding block based on the motion parameter of the previously-reconstructed portion.
 11. The decoder of claim 1, wherein the one or more coding parameters include video parameters and depth parameters both associated with the second coding block in the second view.
 12. An encoder configured for encoding, into a data stream, a multi-view video, the encoder comprising: a view encoder configured for encoding, into the data stream using a processor, first information associated with a first coding block in a first view of a multi-view video signal, wherein the first information is indicative of whether a motion parameter of the first coding block is to (a) be read from the data stream independent of another coding parameter, or (b) reuse one or more coding parameters of a second coding block located in a second view of the multi-view video signal; and encoding, into the data stream using the processor, the motion parameter of the first coding block, if the first information indicates that the motion parameter of the first coding block is to be read from the data stream independent of another coding parameter; encoding, into the data stream using the processor, the one or more coding parameters including a motion parameter of the second coding block in the second view and prediction error data associated with the motion parameter of the first coding block, if the first information indicates that the motion parameter of the first coding block is to reuse the one or more coding parameters from the second coding block in the second view; generating, using the processor, a prediction of the first coding block based at least on the motion parameter of the first coding block; determining, using the processor, residual data associated with the first coding block based on a difference of the first coding block and the prediction of the first coding block; and encoding, into the data stream using the processor, the residual data associated with the first coding block, wherein the first coding block is reconstructed using the prediction of the first coding block, the prediction error data and the residual data to produce a part of a video frame in the first view of the multi-view video.
 13. The encoder of claim 12, wherein the first information is further indicative of whether a motion parameter of the first coding block is to be predicted from a motion parameter of a previously-reconstructed portion of the first view, and if so, the view encoder is configured for encoding, into the data stream using the processor, the motion parameter of the previously-reconstructed portion.
 14. The encoder of claim 12, wherein each of the first and second views comprises different types of information components.
 15. The encoder of claim 14, wherein the different types of information components include a video and a depth map corresponding to the video.
 16. The encoder of claim 15, wherein the first coding block comprises video data and is reconstructed based on a first subset of the one or more coding parameters from the second coding block.
 17. The encoder of claim 16, wherein the first coding block comprises depth data and is reconstructed based on a second subset of the one or more coding parameters from the second coding block.
 18. The encoder of claim 12, wherein the encoder is further configured to encode an intermediate view based on the first and second views.
 19. A non-transitory computer-readable storage medium configured to store information comprising a data stream representing an encoded multi-view video and including: encoded first information associated with a first coding block in a first view of a multi-view signal, wherein the first coding block represents a part of a video frame in the first view and the first information is indicative of whether a motion parameter of the first coding block is to (a) be read from the data stream independent of another coding parameter, or (b) reuse one or more coding parameters of a second coding block located in a second view of the multi-view video signal; an encoded motion parameter of the first coding block, if the first information indicates that the motion parameter of the first coding block is to be read from the data stream independent of another coding parameter; encoded one or more coding parameters including a motion parameter of the second coding block in the second view and prediction error data associated with the motion parameter of the first coding block, if the first information indicates that the motion parameter of the first coding block is to reuse the one or more coding parameters from the second coding block in the second view; and encoded residual data associated with the first coding block based on a difference of the first coding block and a prediction of the first coding block, wherein the prediction of the first coding block is determined using the motion parameter of the first coding block, wherein the first coding block is reconstructed using the prediction of the first coding block, the prediction error data and the residual data to produce the part of the video frame in the first view of the multi-view video.
 20. The non-transitory computer-readable storage medium of claim 19, wherein the first information is further indicative of whether a motion parameter of the first coding block is to be predicted from a motion parameter of a previously-reconstructed portion of the first view, and if so, the data stream further includes an encoded motion parameter of the previously-reconstructed portion. 